Base station, mobile station, and communications method

ABSTRACT

A base station carrying out communications with a mobile station with an Orthogonal Frequency Division Multiplexing (OFDM) method by using a predetermined frequency band out of a transmission band is disclosed. The base station includes an allocation portion that allocates, for a mobile station performing peripheral cell search, a band that includes a center frequency on a raster of a first band and has a bandwidth equal to or greater than a bandwidth of a second band with which a synchronization channel is transmitted.

TECHNICAL FIELD

The present invention generally relates to a technical field of radiocommunications, specifically to a base station, a mobile station, and acommunications method that can be used in various bands.

BACKGROUND ART

In existing communications systems of Wideband Code Division MultipleAccess (W-CDMA), Global System for Mobile communications, and the like,a center frequency of frequency bands used for communications isdetermined to coincide with a predetermined frequency called a raster ora frequency raster. The frequency rasters are arranged, for example,every 200 kHz on a frequency axis.

Therefore, a mobile station can identify the center frequency of anoperator and thus connect to a downlink by searching for the frequencyrasters by turns on the frequency axis (searching every 200 kHz).Downlink cell search is described in Keiji TACHIKAWA, “W-CDMA mobilecommunications method”, Maruzen, Inc., pp. 35-45.

SUMMARY OF INVENTION Problem to be Solved by the Invention

A radio communications system based on an Orthogonal Frequency DivisionMultiplexing (OFDM) method that uses plural wide or narrow bands hasbeen in consideration. The OFDM method is employed because this methodcan provide advantages of efficiently suppressing multi-path propagationinterference, inter-symbol interference, and the like. In such radiocommunications systems, a wideband of, for example, 20 MHz and a band(for example, 5 MHz), which is a part of the wideband, are useddepending on an apparatus configuration of the mobile station, anapparatus configuration of the base station, applications, and the like,which allows various operators to provide service.

For example, spectra in the OFDM method radio communications systemhaving plural bands are shown in FIG. 1. Communications based on theOFDM method can be carried out in both the wide transmission band of 20MHz and the narrow transmission band of 5 MHz in relation to thetransmission bandwidth of 20 MHz.

In such radio communications systems, there exist terminal deviceshaving a receivable bandwidth that is narrower than the transmissionbandwidth of the base station. For example, a terminal device having areceivable bandwidth of 5 MHz carries out communications using afrequency band including a center frequency of the wide bandwidth of 20MHz.

The objective of the present invention is to provide a base station, amobile station and a transmission method that facilitate peripheral celldetection in a mobile transmission system where the OFDM method ofcommunications is carried out in any one of two or more frequency bands.

Means for Solving the Problem

In order to eliminate the above disadvantage, a base station accordingto an embodiment of the present invention 1 carries out communicationswith a mobile station with an Orthogonal Frequency Division Multiplexing(OFDM) method by using a predetermined frequency band out of atransmission band, the base station including an allocation portion thatallocates for a mobile station performing peripheral cell search a bandthat includes a center frequency on a raster of a first band and has abandwidth equal to or wider than a bandwidth of a second band with whicha synchronization channel is transmitted.

With such a configuration, the mobile station can carry out theperipheral cell search using the band including the center frequency.

A communications method according to an embodiment of the presentinvention carries out communications with a mobile station with anOrthogonal Frequency Division Multiplexing (OFDM) method by using apredetermined frequency band out of a transmission band, the methodincluding steps of transmitting a synchronization channel with a secondband including a center frequency on a raster of a first band, andallocating for a mobile station performing peripheral cell search a bandthat includes the center frequency on the raster of the first band andhas a bandwidth equal to or greater than a bandwidth of a second bandfor transmitting the synchronization channel.

With this, the mobile station can carry out the peripheral cell searchusing the center frequency.

A mobile station according to an embodiment of the present inventioncarries out communications due to an Orthogonal Frequency DivisionMultiplexing (OFDM) method with a base station that carries outcommunications by using a predetermined frequency band out of atransmission band, the mobile station including a reception portion thatreceives a downlink signal transmitted using the predetermined frequencyband; a synchronization channel detection portion that detects asynchronization channel transmitted with a second band including acenter frequency on a raster of a first band; a carrier frequencysetting portion that sets a carrier frequency in a band having abandwidth equal to or greater than the second band having the centerfrequency when carrying out peripheral cell search; and a controlportion that carries out switching control of the carrier frequency.

With such a configuration, the mobile station can carry out theperipheral cell search due to the synchronization channel transmittedwith the second band including the center frequency on a raster of thefirst band.

A communications method according to an embodiment of the presentinvention carries out communications due to an Orthogonal FrequencyDivision Multiplexing (OFDM) method with a base station that carries outcommunications by using a predetermined frequency band out of atransmission band, the method including steps of receiving a downlinksignal transmitted using a predetermined frequency band; detecting asynchronization channel transmitted with a second band including acenter frequency on a raster of a first band; setting a carrierfrequency in a band having a bandwidth equal to or wider than a secondband including the center frequency when carrying out peripheral cellsearch; and switching the carrier frequency.

With this, the mobile station can carry out the peripheral cell searchdue to the synchronization transmitted with the second band includingthe center frequency on the raster of the first band.

ADVANTAGE OF THE INVENTION

According to an embodiment of the present invention, there can berealized a base station, a mobile station, and a communications methodthat facilitate peripheral cell detection in a mobile communicationssystem where the OFDM method of communications is carried out in any oneof one or more frequency bands.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an explanatory view illustrating the spectrum of an OFDMmethod radio communications system having plural bandwidths.

FIG. 2 is an explanatory view illustrating a cell search method at thetime of starting communications, according to one embodiment of thepresent invention.

FIG. 3 is a flowchart illustrating shifting to a band to be used after acell search.

FIG. 4 is an explanatory view of the cell search according to theembodiment of the present invention.

FIG. 5 is a block diagram illustrating a transmission apparatusaccording to the embodiment of the present invention.

FIG. 6A is an explanatory view illustrating an SCH transmissionbandwidth.

FIG. 6B is an explanatory view illustrating an SCH transmissionbandwidth.

FIG. 7 is a block diagram illustrating a reception apparatus accordingto one embodiment of the present invention.

FIG. 8 is a block diagram illustrating a reception apparatus accordingto one embodiment of the present invention.

FIG. 9 is an explanatory view illustrating a frequency block allocationmethod according to one embodiment of the present invention.

LIST OF REFERENCE SYMBOLS

-   -   100: transmission apparatus    -   200: reception apparatus

BEST MODE FOR CARRYING OUT THE INVENTION

Based on the following embodiments, a best mode for carrying out thepresent invention is described with reference to the drawings.

The same reference marks are used for elements having the same functionin all the drawings for explaining the embodiments, and repeatedexplanations are omitted.

A radio communications system according to one embodiment of the presentinvention is provided with abase station apparatus and a mobile stationapparatus.

The base station carries out communications based on the OrthogonalFrequency Division Multiplexing (OFDM) method with the mobile station,using a predetermined frequency band out of a transmission band.

In this embodiment, the base station uses a bandwidth of 20 MHz and themobile station uses a bandwidth of 5 MHz, as one example. However, thisembodiment can be applied to a situation where a terminal device uses acertain part of the transmission band of the base station.

First, a cell search method at the time of starting communications isexplained with reference to FIGS. 2 and 3.

The base station and the mobile station can carry out communicationsusing any one of various wide or narrow frequency bands. In thisembodiment, the mobile station has a receivable bandwidth narrower thanthe transmission bandwidth of the base station. In this embodiment, afirst band indicates a transmission signal bandwidth of the basestation, and a second band indicates the narrowest receivable bandwidthamong all receivable bandwidths of all the mobile stations. Therefore,the bandwidth of the first band is equal to or greater than thebandwidth of the second bandwidth. The bandwidth of the second band isequal to transmission bandwidths of a synchronization channel, abroadcast channel, and a control channel in the base station (abandwidth of a frequency block). In addition, the bandwidth of thesecond band is a bandwidth equal to or less than a receivable bandwidthof a terminal device that has the lowest performance among the pluralterminal devices prepared in the system, the terminal devices havingvarious receivable bandwidths, and determined in advance by the system.

The mobile station uses the synchronization channel (SCH) to carry outcell search (step S302). For example, the base station uses apredetermined frequency band out of the transmission band in order totransmit a downlink signal. For example, the base station transmits thesynchronization channel using the second band including a centerfrequency on a raster of the first band. The mobile station receives thedownlink signal.

For example, the mobile station detects a band that includes the centerfrequency of the 20 MHz and has a bandwidth of 1.25 MHz or more, forexample, 1.25 MHz or 5 MHz, out of the 20 MHz spectrum. When the basestation uses a bandwidth of 20 MHz and the mobile station uses the samebandwidth of 20 MHz, the mobile station can easily find the centerfrequency of the 20 MHz band by the cell search.

When the mobile station uses a bandwidth of 5 MHz whose center frequencyis different from the center frequency of the 20 MHz band, the centerfrequency of the 20 MHz band is detected by carrying out correlationdetection in accordance with a predetermined synchronization pattern.The correlation calculation makes it possible to detect the center ofthe band because a correlation value becomes smaller due to only onesub-carrier deviation. As the synchronization pattern, a PN codesequence, a Gold code sequence, and other various sequences may be used.

For example, a 20 MHz band, a 10 MHz band, and a 5 MHz band are preparedin a cell where the mobile station exists, and the mobile station canuse any one of the bands.

Next, the mobile station receives the broadcast channel (BCH)transmitted from the base station and obtains frequency band informationindicated by the base station by using the broadcast band (step S304).The base station maps the synchronization channel over all thesub-carriers and transmits the mapped signal. In addition, the basestation transmits the synchronization channel to all the users using the5 MHz band having the center frequency of the 20 MHz band at the center.The mobile station using the 5 MHz band can detect the center frequencyof the broadcast channel and appropriately demodulate the broadcastchannel transmitted in the 5 MHz band whose center corresponds to thecenter frequency. The broadcast channel includes center frequencyinformation that makes it possible to identify a position of the centerfrequency of the 5 MHz band, which is used as a part of the 20 MHz band.Generally, the center frequency is not on a raster. The center frequencyinformation may include information indicating how far the frequency isaway from the frequency on the raster, for example.

Next, the mobile station demodulates the broadcast channel, reads thecenter frequency information, and adjusts the frequency synthesizer in aradio portion in order to tune in the center of the 5 MHz band, whichthe mobile station uses, to the center frequency included in the centerfrequency information. Namely, the mobile station sets a carrierfrequency to a band that includes the center frequency included in thecenter frequency information and has a bandwidth equal to or more thanthe bandwidth of the second band.

Subsequently, the mobile station receives the control channel (CCH),using the designated band, for example, a rightmost band of 5 MHz out ofthe 20 MHz band, and starts communications (step S306). For example, themobile station receives the CCH in the instructed band, refers tocontrol information (paging information) that is included in the CCH andindicates the presence/absence of an incoming call to the mobilestation, and starts communications when receiving the paging informationto the mobile station. In addition, the mobile station updates thereception frequency band depending on instruction from the base station.

Next, the mobile station carries out communications, using a datachannel in the instructed band (step S308). For example, the mobilestation receives the CCH and the data channel in the instructed band ina predetermined period of time. In addition, the mobile station updatesthe reception frequency band depending on instruction from the basestation. When the mobile station completes the communications using thedata channel in the instructed band, the procedure returns to step S306.

In step S306 and step S308, when the mobile station carries out thecommunications with the base station, using the rightmost band of 5 MHz,the mobile station once shifts the center frequency to the center of thetransmission band and carries out peripheral cell search, in otherwords, detects an SCH and a BCH, in order to search peripheral cellsduring communications, as shown in FIG. 4. The mobile station swiftlyreturns the shifted center frequency to the original center frequencyafter the peripheral cell search, and resumes the communications. Inthis case, the base station allocates a band of 1.25 MHz or more thatincludes the center frequency on the raster of 20 MHz for the mobilestation that carries out the peripheral cell search.

Namely, when a mobile station carrying out communications using afrequency band, which is a part of the system bandwidth, for example, amobile station carrying out communications using a frequency block thatis not the frequency block including the center frequency of the systembandwidth carries out the peripheral cell search, frame timing(including symbol timing) is detected by using the SCH transmitted inthe frequency block including the center frequency. In this case, ascramble code (cell ID) is sent through the control channel of the cellwhere the communications are carried out.

According to this, the peripheral cell search using the SCH needs lesstime. As a result, high quality communications due to fast handover canbe continued.

In this case, the base station does not carry out allocation due toscheduling during which the mobile station may carry out the peripheralcell search. Alternatively, the base station sets up a time period whenthe allocation due to scheduling is not carried out in order to allowthe mobile station to carry out the peripheral cell search, and themobile station carries out the peripheral cell search during the timeperiod.

When the peripheral cell search is carried out, the SCH transmittedthrough a frequency block including the center frequency is required tobe received in addition to the frequency block allocated forcommunications, as described above. By not carrying out the allocationdue to the scheduling in a time period when the peripheral cell searchis carried out, concurrent reception of different frequencies is notnecessary in the mobile station, thereby simplifying a configuration ofthe reception apparatus.

Next, a configuration of a transmission apparatus according to thisembodiment is explained with reference to FIG. 5. The transmissionapparatus is provided in, for example, the base station.

A transmission apparatus 100 includes pilot channel signal generationportions 102 _(i) (1≦i≦2M), L1/L2 control channel signal generationportions 104 _(i), paging channel signal generation portions 106 _(i),and data channel signal generation portions 108 _(i) that are prepareddepending on the number 2M (M: integer, 1 or greater) of frequencyblocks; multiplexing portions 114 _(i) that are prepared depending onthe number 2M of the frequency blocks and connected to the pilot channelsignal generation portions 102 _(i), the L1/L2 control channel signalgeneration portions 104 _(i), the paging channel signal generationportions 106 _(i), and the data channel signal generation portions 108_(i); an IFFT 116 connected to the multiplexing portion 114 _(i); a CPproviding portion 118 connected to the IFFT 116 _(i); and asynchronization channel (SCH) signal generation portion 110 and abroadcast channel signal generation portion 112 that are connected tothe multiplexing portion 114 _(M).

The M-th frequency block includes the center frequency of thetransmission bandwidth of the transmission apparatus 100.

The pilot channel signal generation portions 102 _(i) generate pilotchannel signals and output the pilot channel signals to the multiplexingportions 114 _(i). The L1/L2 control channel signal generation portions104 _(i) generate L1/L2 control channel signals and output the L1/L2control channel signals to the multiplexing portions 114 _(i). Thepaging channel signal generation portions 106 _(i) generate pagingchannel signals and output the paging channel signals to themultiplexing portions 114 _(i). The data channel signal generationportions 108 _(i) generate data channel signals and output the datachannel signals to the multiplexing portions 114 _(i). Thesynchronization channel signal generation portion 110 generates asynchronization channel signal and outputs the synchronization channelsignal to the multiplexing portion 114 _(M). The broadcast channelsignal generation portion 112 generates a broadcast channel signal andoutputs the broadcast channel signal to the multiplexing portion 114_(M).

The multiplexing portions 114 i (i≠M) corresponding to frequency blocksthat are not the M-th frequency block multiplex the pilot channels thattransmit the pilot channel signals, the L1/L2 control channels thattransmit the L1/L2 control channel signals, the paging channels thattransmit the paging channel signals, and the data channels that transmitthe data channel signals, and output the multiplexed signal to the IFFT116.

In addition, the multiplexing portion 114M corresponding to the M-thfrequency block multiplexes the pilot channel that transmits the pilotchannel signal, the L1/L2 control channel that transmits the L1/L2control channel signal, the paging channel that transmits the pagingchannel signal, the data channel that transmits the data channel signal,the synchronization channel that transmits the synchronization channelsignal, and the broadcast channel that transmits the broadcast channelsignal, and outputs the multiplexed signal to the IFFT 116.

The IFFT 116 performs Inverse Fast Fourier Transformation on themultiplexed signal.

The CP providing portion 118 provides a guard interval to the signalthat has been modulated by the OFDM method after the Inverse FastFourier Transformation, and outputs symbols to be transmitted. Then, asignal form of the symbols to be transmitted is transformed into asignal form for transmitting in a radio frequency, and the transmissionis carried out.

In the transmission apparatus 100, the transmission bandwidth of the SCHmay be 2n×a block bandwidth (n: integer, 1 or more).

Because the SCH is transmitted by the center of the system bandwidth,the SCH may be mapped in only a part of the two frequency blocks in thecenter when the block bandwidth and the SCH bandwidth are identical, forexample, when the block bandwidth is 1.25 MHz and the SCH bandwidth is1.25 MHz, as shown in FIG. 6A.

However, by setting the SCH transmission bandwidth to be 2n×the blockbandwidth, the above problem, that is, a problem of the SCH being mappedin only a part of the central two frequency blocks can be solved, asshown in FIG. 6B.

Next, a reception apparatus 200 according to this embodiment of thepresent invention is explained with reference to FIG. 7. The receptionapparatus 200 is provided in, for example, a mobile station.

The reception apparatus 200 includes a carrier frequency multiplicationportion 202 to which a reception signal is input, a filtering portion204 to which an output signal of the carrier frequency multiplicationportion 202 is input, a switch 206 connected to the filtering portion204, a peripheral cell search portion 218 and a communications portion208 that are switchably connected to the switch 206, a handoverdetermination portion 234 connected to the peripheral cell searchportion 218, a peripheral cell search timing control portion 232 servingas a controller, and a carrier frequency setting portion 230 connectedto the peripheral cell search timing control portion 232. Informationindicating an allocation frequency block allocated to a connected cellis input to the carrier frequency setting portion 230, and informationindicating a carrier frequency is input to the carrier frequencymultiplication portion 202. The peripheral cell search timing controlportion 232 controls the switch 206.

In addition, the communications portion 208 includes a synchronizationdetection portion 210 and a CP removal portion 212 that are connected tothe switch 206, an FFT 214 connected to the CP removal portion 212, anda decoding portion 216 connected to the FFT 214. The synchronizationdetection portion 210 is connected to the CP removal portion 212.

In addition, the peripheral cell search portion 218 includes asynchronization timing detection portion 220 that is connected to theswitch 206 and serves as a synchronization channel detector, a CPremoval portion 222 connected to the switch 206, an FFT 224 connected tothe CP removal portion 222, and a cell ID detection portion 226 and areception signal power measurement portion 228 that are connected to theFFT 224. The synchronization timing detection portion 220 is connectedto the CP removal portion 222. The cell ID detection portion 226 and thereception signal power measurement portion 228 are connected to thehandover determination portion 234. An output signal of the cell IDdetection portion 226 is input to the reception signal power measurementportion 228.

The reception signal is multiplied by a carrier frequency set by thecarrier frequency setting portion 230 in the carrier frequencymultiplication portion 202, and then filtered by the filtering portion204.

The peripheral cell search timing control portion 232 controls theswitch 206. The peripheral cell search timing control portion 232switches the switch 206 so that communications or the peripheral cellsearch is carried out at an arbitrary timing. For example, the basestation 100 informs the mobile station 200 of data allocation, forexample, through the CCH, when data are allocated. The mobile station200 determines whether there are data incoming to the same mobilestation 200 in accordance with the received CCH. When it is determinedin accordance with the paging information stored in the CCH as a resultof the reception of the CCH that there are no data incoming to themobile station 200, the mobile station 200 goes into a waiting stateuntil reception of the next CCH. The peripheral cell search timingcontrol portion 232 controls the switch 206 so that the peripheral cellsearch is carried out during the waiting state.

Additionally, in this case, the peripheral cell search timing controlportion 232 outputs to the carrier frequency setting portion 230information indicating that the peripheral cell search is being carriedout. When the carrier frequency setting portion 230 inputs theinformation, the carrier frequency setting portion 230 sets thefrequency corresponding to the M-th frequency block including the centerfrequency of the transmission band of the connected cell, and outputsinformation indicating the frequency to the carrier frequencymultiplication portion 202.

In addition, when the peripheral cell search is being not carried out,the peripheral cell search timing control portion 232 outputs to thecarrier frequency setting portion 230 information indicating that thecommunications are being carried out. When the carrier frequency settingportion 230 inputs the information, the carrier frequency settingportion 230 sets the frequency corresponding to the allocated frequencyblock in accordance with allocation frequency block information of theconnected cell, and outputs information indicating the frequency to thecarrier frequency multiplication portion 202.

When the peripheral cell search is being carried out, thesynchronization channel transmitted from a peripheral base station isused to detect a timing of the synchronization channel by thesynchronization timing detection portion 220, and the CP is removed bythe CP removal portion 222 in accordance with the detected timing. Inaddition, the signal after the CP removal undergoes the Fast FourierTransformation in the FFT 224. The FFT 224 outputs plural sub-carriersignals.

The cell ID detection portion 226 detects the cell ID (peripheral cellID) from the signal that has undergone the Fast Fourier Transformation,and outputs information indicating the cell ID to the handoverdetermination portion 234 and the reception signal power measurementportion 228.

The reception signal power measurement portion 228 measures receptionpower of the signal that has undergone the Fast Fourier Transformation,corresponding to each of the cell IDs, and outputs informationindicating the reception power (peripheral cell reception level) to thehandover determination portion 234.

The handover determination portion 234 determines in accordance with thedetected peripheral cell ID and the peripheral cell reception levelcorresponding to the detected peripheral cell whether the handovershould be carried out. When it is determined that the handover should becarried out, the handover determination portion 234 feedbacks a handoverrequest signal for requesting the handover to the base station.

In addition, when the communications with the connected cell are beingcarried out, predetermined processes are carried out in thecommunications 208.

The synchronization detection portion 210 carries out synchronizationdetection in accordance with the reception signal, and outputsinformation indicating the synchronization timing to the CP removalportion 212. The CP removal portion 212 removes the CP of the receptionsignal in accordance with the synchronization timing. The signal afterthe CP removal undergoes the Fast Fourier Transformation in the FFT 214,and is output to the decoding portion 216. The decoding portion 216carries out a decoding process on the signal that has undergone the FastFourier Transformation, and outputs the decoding result. Specifically,the decoding portion 216 decodes the data channel, the paging channel,and the control channel of the allocated frequency band of the connectedcell. As a result, the decoding result is output from the decodingportion 216.

Next, the transmission apparatus 100 according to another embodiment ofthe present invention is explained.

The transmission apparatus 100 according to this embodiment transmitsthe paging information through the frequency block including the centerfrequency of the entire band.

As shown in FIG. 8, the transmission apparatus 100 is provided, forexample, in a base station, and includes the pilot channel signalgeneration portions 102 _(i) (1≦i≦2M), the L1/L2 control channel signalgeneration portions 104 _(i), and the data channel signal generationportions 108 _(i) that are prepared depending on the number 2M (M:integer, 1 or greater) of frequency blocks; the multiplexing portions114 _(i) that are prepared depending on the number 2M of the frequencyblocks and connected to the pilot channel signal generation portions 102_(i), the L1/L2 control channel signal generation portions 104 _(i), andthe data channel signal generation portions 108 _(i); the IFFT 116connected to the multiplexing portion 114 _(i); the CP providingportions 118 connected to the IFFT 116; and the synchronization channel(SCH) signal generation portion 110, the broadcast channel signalgeneration portion 112, and the paging channel signal generation portion120 that are connected to the multiplexing portion 114 _(M).

The M-th frequency block includes the center frequency of thetransmission bandwidth of the transmission apparatus 100.

The pilot channel signal generation portions 102 _(i) generates thepilot channel signals and output the pilot channel signals to themultiplexing portions 114 _(i). The L1/L2 control channel signalgeneration portions 104 _(i) generate the L1/L2 control channel signalsand output the L1/L2 control channel signals to the multiplexing portion114 _(i). The data channel signal generation portions 108 _(i) generatethe data channel signals and output the data channel signals to themultiplexing portions 114 _(i).

The synchronization channel signal generation portion 110 generates thesynchronization channel signal and outputs the synchronization channelsignal to the multiplexing portion 114 _(M). The broadcast channelsignal generation portion 112 generates the broadcast channel andoutputs the broadcast channel signal to the multiplexing portion 114_(M). The paging channel signal generation portion 120 generates thepaging channel and outputs the paging channel to the multiplexingportion 114 _(M).

The multiplexing portions 114 i (i≠M) corresponding to the frequencyblocks that are not the M-th frequency block multiplex the pilotchannels that transmit pilot channel signals, the L1/L2 control channelsthat transmit the L1/L2 control channel signals, and the data channelsthat transmit the data channel signals, and output the multiplexedsignal to the IFFT 116.

In addition, the multiplexing portion 114 _(M) corresponding to the M-thfrequency block multiplexes the pilot channel that transmits the pilotchannel signal, the L1/L2 control channel that transmits the L1/L2control channel signal, the data channel that transmits the data channelsignal, the synchronization channel that transmits the synchronizationchannel signal, the broadcast channel that transmits the broadcastchannel signal and the paging channel that transmits the paging channelsignal, and outputs the multiplexed signal to the IFFT 116.

The IFFT 116 performs the Inverse Fast Fourier Transformation on themultiplexed signal.

The CP providing portion 118 provides a guard interval to the signalthat has been modulated by the OFDM method after the Inverse FastFourier Transformation, and outputs symbols to be transmitted. Then, asignal form of the symbols to be transmitted is transformed into asignal form for transmitting in a radio frequency, and the transmissionis carried out.

In the transmission apparatus 100, the transmission bandwidth of the SCHmay be 2n×a block bandwidth (n: integer, 1 or more).

Next, a reception apparatus 200 according to another embodiment of thepresent invention is explained. The reception apparatus 200 according tothis embodiment has the same configuration as the reception apparatusexplained with reference to FIG. 7. However, the switch 206 in thereception apparatus 200 in FIG. 7 is not necessary when the receptionapparatus according to this embodiment is in a waiting state.

The transmission apparatus 100 according to this embodiment transmitsthe paging information through the frequency block including the centerfrequency of the entire band. The mobile station 200 determines whetherthere are data incoming to the same mobile station 200 in accordancewith the received CCH. When it is determined in accordance with thepaging information stored in the CCH as a result of the reception of theCCH that there are no data incoming to the mobile station 200, themobile station 200 goes into a waiting state until reception of the nextCCH. The peripheral cell search timing control portion 232 controls theswitch 206 so that the peripheral cell search is carried out during thewaiting state.

According to the transmission apparatus 100 of this embodiment, becausethe paging information is transmitted through the frequency blockincluding the center frequency of the entire band, the frequency bandfor the paging information can be made identical to the frequency bandfor the peripheral cell search. Therefore, when it is determined inaccordance with the paging information that there are no data incomingto the mobile station 200, the peripheral cell search can be carried outwithout changing the carrier frequencies. In other words, time necessaryfor the frequency shifts from the frequency corresponding to theallocated frequency block of the connected cell to the frequency bandincluding the center frequency of the transmission band of the basestation and back to the frequency corresponding to the allocatedfrequency block of the connected cell can be saved. In addition, theperipheral cell search at the time of the waiting state can besimplified.

Next, the transmission apparatus 100 according to yet another embodimentof the present invention is explained.

Because the transmission apparatus 100 according to this embodiment hasthe same configuration as the transmission apparatus 100 explained withreference to FIG. 5, the explanation is omitted.

Next, a reception apparatus 200 according to yet another embodiment ofthe present invention is explained. The reception apparatus 200according to this embodiment has the same configuration as the receptionapparatus explained with reference to FIG. 7. However, the switch 206 inthe reception apparatus 200 in FIG. 7 is not necessary.

The reception apparatus 100 allocates the frequency band including thecenter frequency of the transmission band of the base station for themobile station at the timing of the cell search carried out by themobile station.

For the purpose of illustration, an example where the transmission bandof the base station is divided into three frequency blocks is explainedwith reference to FIG. 9. However, the following explanation holds truewhen the transmission band of the base station is divided into two orfour or more frequency blocks.

Plural mobile stations are grouped, and the divided frequency blocks areallocated for the corresponding groups. The frequency blocks allocatedfor the corresponding groups are changed in a predetermined time cycle.

For example, the base station divides all the users into plural groups,for example, three groups A, B, and C.

A frequency block for the user group A is a frequency block 1, 2, 3, 1,. . . , at the time t, t+1, t+2, t+3, . . . , respectively. In addition,a frequency block for the user group B is a frequency block 2, 3, 1, 2,. . . , at the time t, t+1, t+2, t+3, . . . , respectively. A frequencyblock for the user group A is a frequency block 3, 1, 2, 3, . . . , atthe time t, t+1, t+2, t+3, . . . , respectively.

The base station changes the group to which the mobile station thatrequests execution of the peripheral cell search belongs, to the groupfor which the frequency block including the center frequency isallocated. For example, when the mobile station belonging to the usergroup A requests the execution of the peripheral cell search at the timet, the base station changes the user group to which the same mobilestation belongs from the user group A to the user group B for which thefrequency block including the center frequency of the transmission bandof the connected cell is allocated at the time t, namely, the frequencyblock 2. In this case, the same mobile station continues to belong tothe user group B after the cell search is completed.

In addition, the base station may temporarily allocate the frequencyblock including the center frequency for the mobile station requestingthe execution of the peripheral cell search. For example, the basestation exceptionally allocates the frequency block 2 for the samemobile station during a time period t, and returns the same mobilestation to the user group A time t+1 to remain thereafter.

This international patent application is based on Japanese PriorityApplication No. 2006-010498, filed on Jan. 18, 2006 with the JapanesePatent Office, the entire contents of which are hereby incorporatedherein by reference.

INDUSTRIAL APPLICABILITY

A mobile station, a base station, and a transmission method according tothe present invention are applicable to a radio communications system.

1.-14. (canceled)
 15. A transmission apparatus comprising: asynchronization channel signal generation portion configured to generatea synchronization channel signal; a broadcast channel signal generationportion configured to generate a broadcast channel signal; a pagingchannel signal generation portion configured to generate a pagingchannel signal; an L1/L2 control channel signal generation portionconfigured to generate an L1/L2 control channel signal; a data channelsignal generation portion configured to generate a data channel; amultiplexing portion configured to multiplex the synchronization channelsignal, the broadcast channel signal, the paging channel signal, theL1/L2 control channel signal, and the data channel signal; and atransmission portion configured to transmit a signal multiplexed by themultiplexing portion, wherein a variable-width system band is dividedinto a plurality of frequency blocks, each of which is comprised of aplurality of continuous sub-carriers, in the multiplexing portion, andwherein the multiplexing portion multiplexes the synchronization channelsignal and the broadcast channel signal in a plurality of frequencyblocks whose number is determined so that a width of the plurality ofthe frequency blocks is smaller than the smallest width among widths ofcorresponding variable bands, regardless of the width of the systemband, the plurality of the frequency blocks including a center frequencyof the system band, and multiplexes the paging channel signal, the L1/L2control channel signal, and the data channel signal in another pluralityof frequency blocks that include a frequency block including the centerfrequency of the system band, the number of the another plurality of thefrequency blocks being greater than the number of the plurality of thefrequency blocks in which the synchronization channel signal and thebroadcast channel are multiplexed.
 16. The transmission apparatusclaimed in claim 15, wherein the multiplexing portion multiplexes thesynchronization channel signal in the even number of frequency blocks.17. The transmission apparatus claimed in claim 15, wherein thesynchronization channel signal generated in the synchronization channelsignal generation portion is used for cell search by a mobile station,and wherein the multiplexing portion multiplexes the data channel signaltaking into consideration a cell search timing at the mobile station.18. The transmission apparatus claimed in claim 16, wherein thesynchronization channel signal generated in the synchronization channelsignal generation portion is used for cell search by a mobile station,and wherein the multiplexing portion multiplexes the data channel signaltaking into consideration a cell search timing at the mobile station.19. A transmission method comprising steps of: generating asynchronization channel signal; generating a broadcast channel signal;generating a paging channel signal; generating an L1/L2 control channelsignal; generating a data channel signal; multiplexing thesynchronization channel signal, the broadcast channel signal, the pagingchannel signal, the L1/L2 control channel signal, and the data channelsignal; and transmitting the multiplexed signal, wherein avariable-width system band is divided into a plurality of frequencyblocks, each of which is comprised of a plurality of continuoussub-carriers, in the multiplexing step, and wherein in the multiplexingstep, the synchronization channel signal and the broadcast channelsignal are multiplexed in a plurality of frequency blocks whose numberis determined so that a width of the plurality of the frequency blocksis smaller than the smallest width among widths of correspondingvariable bands, regardless of the width of the system band, theplurality of the frequency blocks including a center frequency of thesystem band, and the paging channel signal, the L1/L2 control channelsignal, and the data channel signal are multiplexed in another pluralityof frequency blocks that include a frequency block including the centerfrequency of the system band, the number of the another plurality of thefrequency blocks being greater than the number of the plurality of thefrequency blocks in which the synchronization channel signal and thebroadcast channel are multiplexed.
 20. The transmission method claimedin claim 19, wherein the synchronization channel signal is multiplexedin the even number of frequency blocks, in the multiplexing step. 21.The transmission method claimed in claim 19, wherein the synchronizationchannel signal is used for cell search by a mobile station, and whereinthe data channel signal is generated taking into consideration a cellsearch timing at the mobile station, in the multiplexing step.
 22. Thetransmission method claimed in claim 20, wherein the synchronizationchannel signal is used for cell search by a mobile station, and whereinthe data channel signal is generated taking into consideration a cellsearch timing at the mobile station, in the multiplexing step.